JP2023027037A - Fan with rotary nozzle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fan assembly including: a fan body; a motor-driven impeller contained within the fan body and arranged to generate an air flow; and a nozzle including a nozzle body having an air inlet arranged to receive the air flow from the fan body and an air outlet arranged to release the airflow from the fan assembly.

SOLUTION: A fan assembly includes: a nozzle retaining mechanism for releasably retaining a nozzle on a fan body; and a rotation mechanism for rotating a nozzle body to the fan body. The nozzle rotation mechanism includes: a rotation motor arranged to drive a driving member; and a driven member arranged to be driven by the driving member to rotate around a rotation axis. The nozzle body includes the driven member and the fan body includes the rotation motor and the driving member.

SELECTED DRAWING: Figure 6

COPYRIGHT: (C)2023,JPO&INPIT

Description

The present invention relates to fan assemblies and nozzles for such fan assemblies.

A conventional domestic fan generally includes a set of blades or vanes mounted for rotation about an axis and a drive for rotating the set of blades to generate an airflow. . The moving and circulating airflow creates a "wind chill" or breeze that results in a cooling effect felt by the user as heat is dissipated through convection and evaporation. The blades are typically mounted in a cage that allows airflow to pass through the housing while preventing a user from contacting the rotating blades during use of the fan.

U.S. Pat. No. 2,488,467 describes a fan that does not use caged blades to project air from the fan assembly. Instead, the fan assembly includes a base that houses the motor driven impeller and draws in the airflow, and annular outlets connected to the base and each located in front of it for discharging the airflow from the fan. and a series of concentric annular nozzles. Each nozzle extends about a cavity axis to define a cavity through which the nozzle extends.

Each nozzle is wing-shaped and thus has a leading edge located aft of the nozzle, a trailing edge located forward of the nozzle, and a chord line extending between the leading and trailing edges. can be considered to have In U.S. Pat. No. 2,488,467, the chord line of each nozzle is parallel to the cavity axis of the nozzle. The air outlet is located on the chord line and is configured to emit airflow in a direction extending along the chord line away from the nozzle.

Another fan assembly that does not use caged blades to project air from the fan assembly is described in WO2010/100451. The fan assembly is connected to a cylindrical base, which also houses a motor-driven impeller and draws the primary airflow into the base through which the primary airflow is discharged from the fan. A single annular nozzle with an annular mouth/outlet. The nozzle defines an opening through which air within the local environment of the fan assembly is drawn by the primary airflow emitted from the aforementioned ports to amplify the primary airflow. The nozzle includes a Coanda surface over which an aperture is arranged to direct the primary airflow. The Coanda surface extends symmetrically about the central axis of the opening such that the airflow generated by the fan assembly is in the form of an annular jet having a cylindrical or frustoconical profile.

A user can change the direction in which the airflow is emitted from the nozzle in one of two ways. The base includes an oscillating mechanism that is actuated to move the nozzle and a portion of the base vertically through the center of the base such that the airflow generated by the fan assembly is swept about an arc of approximately 180°. It can vibrate around an axis. The base also includes a tilting mechanism that allows the nozzle and the upper part of the base to be tilted towards the horizontal at an angle of up to 10° with respect to the lower part of the base.

U.S. Pat. No. 2,488,467 WO 2010/100451 pamphlet

According to a first aspect, a fan assembly is provided. The fan assembly comprises a fan body, a motor driven impeller housed within the fan body and arranged to generate an airflow, and an air inlet and fan assembly arranged to receive the airflow from the fan body. a nozzle including a nozzle body having one or more air outlets positioned to emit an airflow. The fan assembly further includes a nozzle retention mechanism for detachably retaining the nozzle on the fan body and a vibration/rotation mechanism for vibrating/rotating the nozzle body relative to the fan body. The nozzle oscillating/rotating mechanism includes an oscillating/rotating motor arranged to drive a driving member and a driven member arranged to be driven by the driving member to rotate about an oscillating/rotating axis. , the nozzle body includes a driven member, and the fan body includes an oscillating/rotating motor and a drive member.

The present invention is a fan assembly in which a nozzle can rotate and/or oscillate with respect to the body of the fan assembly to redirect airflow emitted from the fan assembly while at the same time performing cleaning, for example, cleaning. Alternatively, a fan assembly is provided in which the nozzle can be detached and removed from the fan assembly for replacement. In contrast, some conventional fan assemblies allow the nozzle to be removed from the body of the fan assembly, but any redirection of the airflow due to rotation or vibration requires the body of the fan assembly to move downward. It is necessary to have the upper part rotatable with respect to the side parts, which usually introduces limitations and complications to construction and manufacturing.

Preferably, the nozzle retention mechanism includes a first configuration in which the nozzle is retained on the fan body (i.e., prevented from being separated from the fan body) when placed on the fan body; and a second configuration that is released for removal from the body. Preferably, the nozzle retention mechanism is biased toward the first configuration. The nozzle retention mechanism may comprise a biasing/resilient member for biasing the nozzle retention mechanism toward the first configuration.

The nozzle retention mechanism may comprise a retention element movable relative to the nozzle and fan body between first and second configurations. Preferably, the nozzle retention mechanism includes a manually actuable member for effecting movement of the retention element from the first configuration to the second configuration. The manually actuatable member and retaining element may be formed as a single pivotally mounted component, with the manually actuatable member provided at one end and the retaining element provided at the other end. Thus, pressure acting on the manually actuatable member causes the catch to pivot such that the retaining element moves to the second configuration for removing the nozzle from the fan body. A retaining element and a manually actuatable member can be provided on the nozzle.

Preferably, the manually actuatable member includes a depressible button. Preferably the retaining element comprises a catch. Preferably, the fan body is engaged by a catch of the nozzle retention mechanism, thereby retaining the nozzle on the body in the first configuration when the nozzle is positioned on the fan body. It has a flange/lip. Preferably, the flange/lip extends to at least partially surround the axis of rotation/oscillation. More preferably, the flange/lip extends around the entire range of rotation/vibration of the nozzle body relative to the fan body.

Preferably, the driven member comprises a set of teeth arranged on a peripheral portion of the driven member arranged to mesh with teeth provided on the drive member when the nozzle is positioned on the fan body. . Preferably, the driving member comprises a pinion and the driven member comprises an at least partially circular or arcuate rack or ring gear.

Preferably, the pinion comprises a spur or straight cut gear having radially projecting teeth that are linear and aligned parallel to the axis of rotation. Preferably, the top of the pinion (ie, arranged to face the nozzle when the nozzle is attached to the fan body) is chamfered. Both roots and teeth on the top of the gear can be chamfered. The root angle (θ) of the chamfered portion is preferably about 45 degrees.

Preferably, the rack includes a set of teeth arranged to mesh with teeth provided on the pinion when the nozzle is positioned on the fan body. The rack may comprise a spur rack or straight cut rack having a plurality of radially projecting teeth that are linear and aligned parallel to the axis of rotation. Preferably, the lower portion of the rack (ie arranged so that the nozzle faces toward the fan body when attached to the fan body) is chamfered. Both the root and the teeth of the lower portion of the rack can be chamfered. The angle at the root of the chamfer may be about 45 degrees.

The nozzle body may comprise at least one stop positioned to prevent rotation of the nozzle body beyond the end of its rotational/oscillating range. Preferably, the nozzle body comprises two stops positioned to prevent rotation of the nozzle body beyond the first and second opposite ends of the rotation/oscillation range of the nozzle body. The or each stop may further be arranged to prevent the nozzle from being mounted on the fan body when the nozzle body is oriented relative to the fan body out of rotation/vibration range of the nozzle body. The fan body may comprise a raised portion contacted by the or each stop at the end of the oscillation range of the nozzle body and arranged to thereby prevent rotation beyond the end of the range. Preferably, the raised portion of the fan body is also arranged to be contacted by the or each stop as the nozzle body moves toward the fan body while being oriented out of the oscillation range of the nozzle with respect to the fan body. be done.

The fan assembly may further include a nozzle orientation detection mechanism arranged to detect the orientation of the nozzle body relative to the fan body when the nozzle is attached to the fan body. The nozzle orientation detection mechanism can be configured to detect in which of the two halves of the rotation/oscillation range the nozzle body is currently in. Preferably, the orientation detection mechanism is arranged to be detected by a photointerrupter provided on the fan body and by the photointerrupter when the nozzle body is in one of the two halves of the rotational/oscillating range. and an at least partially circular or arcuate screen/shield. Preferably, the screen/shield depends on or protrudes from the nozzle body.

Preferably, the nozzle further comprises a base member arranged to contact the fan body when the nozzle is attached to the fan body, the nozzle body being rotatable relative to the base member. The nozzle body may comprise a plurality of runners arranged to retain the base member while allowing the base member to rotate relative to the nozzle body. Preferably, the base member comprises a flange/rail disposed and sliding within each of the plurality of runners. The base member can further include an annular plate. A flange/rail can then be placed on the annular plate and protrude radially to the vibration axis.

Preferably, the fan assembly further includes a filter assembly mounted over at least a portion of the fan body. Preferably, at least the upper section of the fan body is cylindrical and the filter assembly is concentrically mounted over at least a portion of the upper section of the fan body. Preferably, the filter assembly is cylindrical to surround the entire circumference of the upper section of the fan body. The base member of the nozzle may include an upper filter seal element positioned to contact the upper surface of the filter assembly thereby forming a seal between the lower surface of the base member and the upper surface of the filter assembly. Preferably, the upper filter seal element is arranged to contact a surface of the fan body thereby forming a seal between the lower surface of the base member and the fan body.

Preferably, the fan body includes an upper section and a lower section, the lower section providing a filter seat on which the filter assembly is supported. A filter assembly can then be mounted over at least a portion of the upper section of the fan body. Preferably, the filter seat includes a lower filter sealing element arranged to seal against the lower surface of the filter assembly when attached to the fan assembly. Preferably, the filter seat is provided within the fan body. An upper section of the fan body can provide a filter compartment within which a filter assembly can be placed. Preferably, the upper section of the filter compartment has an open top end that allows the filter assembly to be inserted and removed from the compartment. Preferably, the open top end of the compartment is covered by the nozzle when the nozzle is attached to the fan body.

A lower section of the fan body can house various electronic components of the fan assembly. Preferably, the fan body lower section houses a display that is visible through an aperture or window formed in the outer surface of the fan body lower section. Preferably, the lower section of the fan body provides a base (ie, lower surface) on which the fan assembly rests. The edges of the filter seat may be provided with one or more tapered/slanted ribs/segments that align the filter assembly on the fan body. Preferably, these ribs/segments project radially outwardly from the lower edge of the inner wall of the upper section of the fan body.

The fan body may further include an inner wall and an outer wall spaced from the inner cylindrical wall to define a filter compartment in which the filter assembly is placed/disposed. Both the inner and outer walls are cylindrical, with the outer wall surrounding and concentric with the inner wall, thereby defining an annular filter compartment. The filter assembly is cylindrical, concentrically disposed within the inner wall, and supported on the filter seat. Both the inner and outer walls can be provided with air inlets through which air can pass. Preferably, the inner wall defines an inner compartment in which the motor driven impeller is supported/arranged. A motor driven impeller may be located within an impeller housing located within the upper portion of the inner compartment.

A fan assembly may include more than one nozzle retention mechanism. Preferably, the fan assembly includes a pair of nozzle retention features diametrically opposed on the fan assembly.

According to a second aspect, a nozzle for a fan assembly is provided. The nozzle comprises a nozzle body having an air inlet positioned to receive airflow from the body of the fan assembly and one or more air outlets positioned to emit airflow from the nozzle. The nozzle further includes a nozzle retention mechanism for detachably retaining the nozzle to the body of the fan assembly, and a driven member arranged to be driven by the drive member to rotate the nozzle body about the axis of rotation. , provided. The driven member is arranged to engage a drive member provided on the body of the fan assembly.

Preferably, the nozzle retention mechanism has a first configuration in which the nozzle is retained on the body of the fan assembly and a second configuration in which the nozzle is released for removal from the body of the fan assembly. Preferably, the nozzle retention mechanism is biased toward the first configuration. The nozzle retention mechanism can comprise a biasing/resilient member for biasing the nozzle retention mechanism toward the first configuration.

Preferably, the nozzle retention mechanism comprises a retention element movable relative to the nozzle body between a first configuration and a second configuration. Preferably, the nozzle retention mechanism comprises a manually actuatable member for effecting movement of the retention element from the first configuration to the second configuration. The manually actuatable member and retaining element may be formed as a single pivotally mounted component, with the manually actuatable member provided at one end and the retaining element provided at the other end. Thus, pressure acting on the manually actuatable member causes the catch to pivot such that the retaining element moves to the second configuration for removing the nozzle from the fan body.

The manually actuatable member can include a depressible button. The retaining element can have a catch.

Preferably, the driven member comprises an at least partially circular or arcuate rack or ring gear. Preferably, the rack includes a set of teeth arranged to mesh with teeth provided on the pinion when the nozzle is positioned on the fan body. The rack may comprise a spur rack having a plurality of radially projecting teeth aligned linearly and parallel to the axis of rotation. Preferably, the edges of the lower section of the rack (ie arranged to face towards the fan body when the nozzle is attached to the fan body) are chamfered. Both the root and the teeth of the lower portion of the rack can be chamfered. The angle at the root of the chamfer may be about 45 degrees.

The nozzle body may comprise at least one stop positioned to prevent rotation of the nozzle body beyond the end of its rotational/oscillating range. Preferably, the nozzle body comprises two stops positioned to prevent rotation of the nozzle body beyond the first and second opposite ends of the rotation/oscillation range of the nozzle body. The or each stop may further be arranged to prevent the nozzle from being mounted on the fan body when the nozzle body is oriented relative to the fan body out of rotation/vibration range of the nozzle body.

Preferably, the nozzle further comprises a base member arranged to contact the fan body when the nozzle is attached to the fan body, the nozzle body being rotatable relative to the base member. The nozzle body may comprise a plurality of runners arranged to retain the base member while allowing the base member to rotate relative to the nozzle body. Preferably, the base member comprises a flange/rail disposed and sliding within each of the plurality of runners. The base member can further include an annular plate. A flange/rail can then be placed on the annular plate and protrude radially to the vibration axis.

The base member is further adapted to contact the upper surface of the filter assembly when the nozzle is attached to the body of the fan assembly, thereby forming a seal between the lower surface of the base member and the upper surface of the filter assembly. an upper filter sealing element positioned in the . Preferably, the upper filter seal element is arranged to contact a surface of the fan assembly body, thereby forming a seal between the lower surface of the base member and the fan assembly body.

A nozzle can be provided with two or more nozzle retention mechanisms. Preferably, the nozzle includes a pair of nozzle retention features diametrically opposed on the fan assembly.

According to a further aspect, a fan assembly comprising a fan body, a motor driven impeller housed within the fan body and arranged to generate an airflow, and arranged to receive the airflow from the fan body. a nozzle for releasably retaining the nozzle on the fan body; A fan assembly is provided that includes a retention mechanism and a rotation mechanism for rotating the nozzle body relative to the fan body. The nozzle rotation mechanism includes a rotary motor arranged to drive a driving member and a driven member arranged to rotate about an axis of rotation driven by the driving member, the nozzle body being driven by the driven member. The fan body includes a rotating motor and a drive member. The driven member includes a pinion and the driving member includes an at least partially circular or arcuate rack. The pinion comprises a linear gear with a chamfered upper portion and the rack comprises a linear rack with a chamfered lower portion.

According to yet another aspect, a fan assembly includes a fan body, a motor driven impeller housed within the fan body and arranged to generate an airflow, and a fan body to receive the airflow from the fan body. a nozzle including a nozzle body having an air inlet positioned thereon and one or more air outlets positioned to discharge airflow from the fan assembly; and a nozzle for releasably retaining the nozzle on the fan body. A fan assembly is provided that includes a nozzle retention mechanism and a rotation mechanism for rotating the nozzle body relative to the fan body. The nozzle rotating mechanism comprises a rotating motor arranged to drive the driving member, and a driven member arranged to rotate about an axis of rotation driven by the driving member, and the nozzle body is driven by the driven member. The fan body includes a rotating motor and a drive member. The nozzle retention mechanism has a first configuration in which the nozzle is retained in the fan body and a second configuration in which the nozzle is released for removal from the fan body. The nozzle retention mechanism further comprises a catch on the nozzle movable relative to both the nozzle and the body between the first configuration and the second configuration, the fan body being engaged by the catch of the nozzle retention mechanism. , with a circular or arcuate lip arranged to retain the nozzle on the body thereby in the first configuration.

According to yet another aspect, a fan assembly includes: a fan body; a filter assembly mounted over at least a portion of the fan body; A nozzle having a motor driven impeller positioned, an air inlet positioned to receive airflow from the fan body, and one or more air outlets positioned to discharge the airflow from the fan assembly. A fan assembly is provided that includes a nozzle that includes a body. The fan assembly further includes a nozzle holding mechanism for detachably holding the nozzle on the fan body, and a rotating mechanism for rotating the nozzle body with respect to the fan body. The nozzle further includes a base member positioned to contact the fan body when the nozzle is attached to the fan body, the nozzle body being rotatable relative to the base member. The nozzle base member further includes an upper filter seal element positioned to contact the upper surface of the filter assembly.

1 is a front view of one embodiment of a fan assembly; FIG. Figure 2 is a side view of the fan assembly of Figure 1; Figure 2 is an isometric view of the fan assembly of Figure 1; Figure 2 is an isometric view of the fan assembly of Figure 1 with the nozzle separated from the body; Figure 2 is a cross-sectional side view through the fan assembly of Figure 1; 2 is a cross-sectional side view through the fan assembly of FIG. 1, with the nozzle separated from the body; FIG. Figure 2 is a cross-sectional front view through the fan assembly of Figure 1; Figure 2 is an isometric view of the body of the fan assembly of Figure 1; 2 is an enlarged cross-sectional view through the fan assembly of FIG. 1 showing the vibrating mechanism; FIG. Figure 2 is an isometric view of the body of the fan assembly of Figure 1 with the filter assembly removed from the body; FIG. 4 is a cross-sectional side view through a filter assembly suitable for use with the fan assemblies described herein; Figure 2 is a cross-sectional side view of the nozzle of the fan assembly of Figure 1; Figure 2 is a cross-sectional front view of the nozzle of the fan assembly of Figure 1; Figure 2 is a cross-sectional rear view of the nozzle of the fan assembly of Figure 1; Figure 2 is an isometric view of the nozzle lower end of the fan assembly of Figure 1; Figure 13 is an isometric front view of the valve member of the nozzle of Figure 12; Figure 13 is an end-on view of the valve member of the nozzle of Figure 12; Figure 13 is a cross-sectional side view of the valve member of the nozzle of Figure 12; Figure 13 is a simplified vertical cross-sectional view of the nozzle of Figure 12 showing the valve member in the second end position; Figure 13 is a simplified vertical cross-sectional view of the nozzle of Figure 12 showing the valve member in the first end position;

Here, a single air stream, e.g., a single air source, is input and emitted from the nozzle without the need to tilt either the nozzle or the fan assembly to which the nozzle is attached. A nozzle for a fan assembly is described that allows the airflow to be manipulated to change the direction of the airflow. As used herein, the term "fan assembly" refers to a fan assembly configured to generate and deliver airflow for the purposes of thermal comfort and/or environmental or atmospheric control. Point. Such fan assemblies may generate one or more of dehumidified airflows, humidified airflows, purified airflows, filtered airflows, cooling airflows, and heated airflows. However, the fan assembly is equally suitable for generating airflow for other purposes, such as for hair dryers or other hair care appliances.

The nozzle has an air inlet, first and second air outlets for emitting an air flow, the first and second air outlets being oriented in a converging direction, and first and second air outlets. and a valve for controlling the air outlet. The valve includes one or more valve members movable to simultaneously adjust the size of the first air outlet and inversely adjust the size of the second air outlet. The one or more valve members are arranged in a first end position in which the first air outlet is open to the maximum source and the second air outlet is maximally closed, and the first air outlet is in the maximum source. is movable over a range of positions between a second end position where the second air outlet is fully closed and the second air outlet is maximally open. The valve is further configured such that the size difference between the first air outlet and the second air outlet when the one or more valve members are in the first end position is such that the one or more valve members are in the second end position. It is arranged to be larger than the size difference between the first air outlet and the second air outlet when in the open position.

As used herein, the term "air outlet" refers to the portion of the nozzle through which airflow exits the nozzle. In particular, in the embodiments described herein, each air outlet comprises a conduit or duct defined by a nozzle through which airflow exits the nozzle. Therefore, each air outlet can alternatively be referred to as an exhaust. This is in contrast to other parts of the nozzle that are upstream from the air outlet and are responsible for directing the air flow between the air inlet and the air outlet of the nozzle.

By varying the size of the first air outlet (i.e., the aperture area) relative to the size of the second air outlet, the proportion of airflow emitted through each of the first and second air outlets is also change, thereby resulting in a change in the profile of the airflow generated by the nozzle. In particular, the first and second air outlets are directed in a converging direction so that the first and second air streams collide to form a single combined air stream that is directed away from the nozzle. The angle or vector at which the composite airflow is projected from the nozzle strongly depends on the relative strengths of the first and second airflows. Thus, by moving one or more valve members to adjust the size of the first air outlet relative to the second air outlet, by varying their respective strengths, the direction of the combined air flow can be adjusted. can be changed. This arrangement means that the system is subject to a constant load, as the overall size of the collective air outlets remains constant. This means that if the airflow emitted from the nozzle can be controlled and directed back and forth, the operating point of the compressor or other means supplying the airflow to the nozzle also remains constant. In addition, this allows the overall system pressure to be reduced, making the system more energy efficient and quieter.

The nozzle preferably comprises an external guide surface adjacent to the air outlet. This external guide surface comprises the outer surface of the fan assembly and may be flat or at least partially convex. In that case, the first and second air outlets may each be oriented to direct the airflow emitted over at least a portion of the outer guide surface. Preferably, the first and second air outlets are oriented to emit airflow in a direction substantially parallel to the portion of this external guide surface adjacent to the air outlets. In that case, the outer guide surface is shaped to deflect or turn away from the direction in which the air flows are emitted from the first and second air outlets so that these air flows are directed away from the outer guide surface. It is preferable to be able to collide at/around the convergence point without interference. Ejecting the airflow across the outer guide surface minimizes airflow turbulence as it first exits the nozzle, and subsequent departure of the airflow from the outer guide surface causes the outer guide surface to be ejected. A detachment bubble can be formed between the converging airflows and the convergence points. The formation of a separation bubble can help stabilize a composite jet or multiple airflows that are formed when two opposing airflows collide.

1, 2 and 3 are external views of one embodiment of a fan assembly 1000. FIG. 1 shows a front view of fan assembly 1000, FIG. 2 shows a side view of fan assembly 1000, and FIG. 3 is an isometric view of fan assembly 1000. FIG. The fan assembly 1000 includes a body or stand 1100 housing a motorized impeller configured to generate airflow through the fan assembly, and removably mounted on the body 1100 such that the airflow from the body 1100 and a nozzle 1200 that is removable and configured to emit airflow from the fan assembly 1000 . Accordingly, FIG. 4 shows an isometric view of fan assembly 1000 with nozzle 1200 separated from body 1100 .

5 shows a cross-sectional side view through the fan assembly 1000, FIG. 6 shows a cross-sectional side view through the fan assembly 1000 with the nozzle 1200 separated from the body 1100, and FIG. A cross-sectional front view through assembly 1000 is shown. Turning now to FIG. 8, an isometric view of the body of fan assembly 1000 is shown. In the illustrated embodiment, the body 1100 comprises a cylindrical outer housing/casing 1101 having side walls, a closed bottom end and an open top end, the closed bottom end whereby the fan assembly 1000 is Providing a base 1102 (ie, lower surface) on which to rest/support, the air inlets 1103 of the body 1100 are provided in the side walls of the outer casing 1101 . In the illustrated embodiment, the air inlet 1103 into the body 1100 of the fan assembly 1000 comprises an array of apertures formed in the side wall of the outer casing 1101, but the air inlet 1103 is instead a window formed in the side wall. It can also have one or more grilles or meshes mounted therein.

The interior of casing 1101 is then separated into a lower section and an upper section at the lower end of casing 1101 by pedestal 1104 located within casing 1101 . Specifically, pedestal 1104 comprises a generally circular surface/floor that extends across the entire cross-sectional area within casing 1101 and a generally cylindrical sidewall that depends/protrudes downwardly from that surface and separates the surface from the lower end of casing 1101 . and The raised surface of the cradle 1104 thereby divides the interior of the outer casing 1101 into an upper section and a lower section, the lower section comprising the portion of the interior of the casing 1101 below the surface, the upper section includes the portion above the surface.

The lower section provides a compartment 1105 in which the various electronic components of the fan assembly 1000 are housed, and a cradle overlies the electronic components and separates them from the rest of the fan assembly. form a cover; For example, these electronic components typically include control circuitry 1106, power connections, and one or more sensors such as infrared sensors, dust sensors, and the like. Additionally, the lower section of the body can also house one or more wireless communication modules such as Wi-Fi, Bluetooth, etc., as well as any associated electronics. The lower section may further comprise an electronic display 1107 visible through an opening or at least partially transparent window provided in the lower section. In the illustrated embodiment, the electronic display 1107 is mounted in the lower section and is exposed to both corresponding openings in the sidewalls of the cradle 1104 and transparent windows in the sidewalls of the outer casing 1101. Provided by an aligned LCD display.

The upper section then provides separate compartments 1108 in which the various components of the fan assembly 100 involved in generating the airflow are housed, and the pedestal 1104 supports these components thereon. provide a basis for In the illustrated embodiment, an inner wall 1109 is provided within the upper section that is spaced from the inner surface of the side wall of the outer casing 1101 . The inner wall 1109 thereby separates the upper section into an inner compartment in which the motor driven impeller 1110 is housed and an outer compartment in which the filter assembly 1111 can be placed. Specifically, inner wall 1109 comprises an open cylinder supported on the upper surface of pedestal 1104 provided at the lower end of outer casing 1101, thereby providing a generally cylindrical inner compartment to which motor driven impeller 1110 is mounted. determine. The inner wall 1109 is also smaller in diameter than the cylindrical outer casing 1101 and is concentrically disposed within the outer casing 1101 such that the outer compartment defined between the outer casing 1101 and the inner wall 1109 is annular and the inner compartment surround the perimeter of FIG. 6 shows a cross-sectional side view through fan assembly 1000, where filter assembly 1111 is attached to the fan to clearly show the outer compartment defined between outer casing 1101 and inner wall 1109 of fan body 1100. It has been removed from the main body 1100 .

A lower portion of the inner wall 1109 is provided with an array of apertures 1112 that allow air to enter the inner compartment and thus provide an air inlet into the inner compartment. A ledge/shelf 1113 then extends radially inwardly from the inner wall 1109 above the aperture array 1112 and a motor driven impeller 1110 is then supported by the ledge 1113 within the upper portion of the inner compartment. In the illustrated embodiment, the inner compartment houses an impeller housing 1114 extending around the impeller 1110, the impeller housing 1114 having a first end defining an air inlet 1115 thereof and an air inlet 1115 opposite the first end. and a second end that defines an air outlet 1116 of the impeller housing 1114 . The impeller housing 1114 is arranged such that the longitudinal axis of the impeller housing 1114 is collinear with the longitudinal axis (X) of the main body 1100 of the fan assembly 100 and the air inlet 1115 of the impeller housing 1114 is aligned with the air outlet 1116. It is aligned within the inner compartment/outer casing 1101 so as to be located below. Impeller housing 1114 includes a generally frustoconical lower wall 1114a and a generally frustoconical upper wall 1114b. A generally annular inlet member 1117 is then connected to the bottom of the lower wall 1114b of the impeller housing 1114 for guiding incoming airflow into the impeller housing 1114 . The air inlet 1115 of the impeller housing 1114 is thus defined by an annular inlet member 1117 provided at the open lower end of the impeller housing 1114 .

In the illustrated embodiment, the impeller 1110 is in the form of a mixed flow impeller having a generally conical hub, a plurality of impeller blades connected to the hub, and a generally conical shape connected to the blades surrounding the hub and blades. a trapezoidal shroud; Impeller 1110 is coupled to a rotatable shaft 1118 that extends outwardly from a motor 1119 housed within a motor housing 1120 located within impeller housing 1114 . In the illustrated embodiment, motor 1119 is a DC brushless motor having a speed that is variable by control circuit 1106 in response to user-provided control inputs.

Motor housing 1120 includes a generally frusto-conical lower portion 1120a that supports motor 1119 and a generally frusto-conical upper portion 1120b that is coupled to lower portion 1120a. Shaft 1118 projects through an aperture formed in lower portion 1120 a of motor housing 1120 to allow impeller 1110 to be coupled to shaft 1118 . The upper portion 1120b of the motor housing 1120 further comprises an annular diffuser 1120c in the form of curved blades projecting from the outer surface of the upper portion 1120b of the motor housing 1120. As shown in FIG. A wall of impeller housing 1114 surrounds and is spaced from motor housing 1120 such that impeller housing 1114 and motor housing 1120 define an annular air flow path therebetween extending through impeller housing 1114 . An air outlet 1116 of the impeller housing 1114 through which the airflow generated by the motor driven impeller 1110 is discharged is then defined by an upper portion 1120b of the motor housing 1120 and a top wall 1114b of the impeller housing 1114. .

A nozzle seat/mount cradle 1121 is then positioned within the upper end of the inner compartment above the impeller housing 1114 . The nozzle seat 1121 has a circular cross-section and includes a lower portion 1121a connected to an upper portion 1121b that fits around the upper wall 1114b of the impeller housing 1114. As shown in FIG. The center of the nozzle seat 1121 is provided with a bearing 1122 which forms part of a slide bearing/journal bearing assembly which is described in more detail below. In the illustrated embodiment, bearing 1122 comprises a hollow cylinder 1122a housing a self-lubricating bushing or sleeve bearing 1122b. For example, such a self-lubricating bushing may comprise an at least partially porous tubular member impregnated with lubricant, preferably having a lubricant content of 12-20%. At the upper open end of bushing 1122b, the inner edge is chamfered to provide a surface that slopes radially inward toward the hollow interior of bushing 1122b.

The nozzle seat 1121 in turn further comprises an annular vent/opening 1123 surrounding the central bearing 1122 through which airflow discharged from the impeller housing 1114 passes through the annular vent 1123 in the nozzle seat 1121 to the fan assembly. As it exits the body 1100 of the 1000 , it aligns with the air outlet 1116 of the impeller housing 1114 . Specifically, the annular vent 1123 of the nozzle seat 1121 is defined by a plurality of curved blades 1124 projecting from the outer surface of the central bearing 1122 and connecting the central bearing 1122 to the outer annular portion of the nozzle seat 1121 . The curved blades 1124 of the nozzle seat 1121 are preferably aligned with the curved blades of an annular diffuser 1120 c provided at the air outlet 1116 of the impeller housing 1114 .

Next, the nozzle seat 1121 further comprises a main body outlet seal member 1125 arranged around the outer circumference of the annular vent 1123, which seals air at the interface between the air outlet 1123 of the main body 1100 and the air inlet of the nozzle 1200. To prevent leakage, the nozzle 1200 contacts the bottom of the nozzle 1200 when attached to the body 1100 of the fan assembly 1000 to form a seal. In the illustrated embodiment, outlet seal member 1125 is annular, is retained within a corresponding groove or slot provided in nozzle seat 1121, and is conveniently formed of a resilient material such as rubber. Nozzle seat 1121 in turn further comprises an annular nozzle alignment surface 1126 located on the outer periphery of outlet seal member 1125 , which slopes downwardly toward outlet seal member 1125 , thus facilitating nozzle 1200 . It is arranged to help guide the air inlet into alignment with the air outlet 1123 of the body 1100 .

Nozzle seat 1121 then further comprises an arcuate recess 1127 surrounding most of annular vent 1123, which extends around the outside of the perimeter of nozzle alignment surface 1126 and thus annular vent 1123 and the outlet seal. Disposed radially outwardly relative to member 1126 . The outer wall of the arcuate recess 1127 is provided with a radially inwardly projecting ledge/lip 1128 to partially overhang the arcuate recess.

The nozzle seat 1121 further includes a drive portion of a rotation/vibration mechanism for vibrating at least a portion of the nozzle 1200 with respect to the fan body 1100 , and the drive portion is driven by a rotation/vibration motor 1129 and a drive member 1130 arranged to be driven. In the illustrated embodiment, the rotary/oscillating motor 1129 is positioned in/under the raised portion of the nozzle seat 1121 located between the two ends of the arcuate recess 1127, the shaft of the rotary/oscillating motor 1129 extending through the nozzle seat. 1121 protruding from the raised portion aperture. The drive member is then provided by a pinion 1130 mounted on a projecting portion of the shaft above the raised portion of the nozzle seat 1121 . Therefore, the pinion 1130 is positioned above the top surface of the nozzle seat 1121 .

FIG. 9 shows an enlarged cross-sectional view through fan assembly 1000 displaying the rotation/oscillation mechanism. In this embodiment, the pinion 1130 comprises a spur gear with radially projecting teeth that are linear and aligned parallel to the axis of rotation, but the upper portion of the gear is chamfered. Specifically, both the root and the teeth of the upper portion of the gear are chamfered, and the angle (θ) of the chamfered portion root is preferably about 45 degrees. In other words, pinion 1130 comprises a linear gear having a cylindrical lower portion and a conical/frustoconical upper portion such that the upper portion has the form of a straight bevel gear.

In addition, nozzle seat 1121 further includes photointerrupter 1131 as part of a mechanism for detecting the orientation of nozzle 1200 when attached to main body 1100 . In this regard, a photointerrupter is a photosensor comprising a light-emitting element and a light-receiving element aligned to face each other with a gap defined therebetween. The photointerrupter then operates by detecting when an object comes between the elements and blocks light from the light emitting element from reaching the light receiving element. In general, infrared emitters are usually used as light-emitting elements, whereas infrared detectors are used as light-receiving elements. In the illustrated embodiment, the photointerrupter 1131 is configured such that the gap between the light emitting element and the light receiving element is aligned with the arcuate recess 1127, with the light emitting element on one side of the gap and the light emitting element on the other side at approximately the midpoint of the arcuate recess 1127. It is arranged so that the light receiving element is positioned.

As described above, the outer section of the upper section of body 1100 houses filter assembly 1111 therein such that filter assembly 1111 is downstream of air inlet 1103 of body 1100 and upstream of motor driven impeller 1110 . Provide a space that can be placed in As a result, air drawn into the interior of body 1100 by impeller 1110 is filtered prior to passing through impeller 1110 . This helps remove particles that could damage the fan assembly 1000 and also ensures that the air emitted from the nozzle 1200 is free of particulates. In addition, the filter assembly 1100 includes at least one chemical filter that serves to remove various potentially health hazard chemicals from the airflow so that the air emitted from the nozzle is purified. Preferably, it further comprises a filtering medium.

10 shows an isometric view of the body 1100 of the fan assembly 1000 with the filter assembly 111 removed from the body 1100. FIG. In the illustrated embodiment, an annular outer compartment defined by inner wall 1109 surrounds the outer periphery of the inner compartment and has an open top end that allows filter assembly 1111 to be inserted into and removed from the outer compartment. have Thus, filter assembly 1111 has the shape of a hollow cylinder arranged to fit concentrically over inner wall 1109 within the annular outer compartment, such that filter assembly 1111 surrounds the entire outer circumference of inner wall 1109 . It's becoming Specifically, the filter assembly 1111 comprises one or more filtration media 1132, 1133 formed in a hollow cylindrical shape, wherein two opposing ends of the one or more filtration media are each: It is covered by filter end caps 1135,1136.

FIG. 11 shows a cross-sectional side view through a filter assembly 1111 suitable for use with the fan assembly 1000 described herein. In the illustrated embodiment, the filter assembly 1111 is disposed over the chemical filtration media layer 1132 and the particulate filtration media layer upstream of the chemical filtration media layer 1132 . 1133 and an outer mesh layer 1134 disposed over the outer surface of the particulate filtration media layer 1133 and thus upstream of the particulate filtration media layer 1133 . A first end cap 1135 is then placed over the first end of each of the particulate filtration media layer 1133, the chemical filtration media layer 1132 and the outer mesh layer 1134, while the second end cap 1135 is placed over the second end. A cap 1136 is positioned over the second end of each of particulate filtration media layer 1133 , chemical filtration media layer 1132 and outer mesh layer 1134 . For example, particulate filtration media 1133 may comprise a pleated polytetrafluoroethylene (PTFE) or glass microfiber nonwoven, while chemical filtration media 1132 may comprise activated carbon filtration media such as carbon cloth. can. Filter end caps 1135, 1136 can then be molded from a plastic material and attached/glued to the ends of the filter media using an adhesive. In a preferred embodiment, one of the filter end caps 1136 further comprises one or more tabs that project longitudinally away from the filter end cap 1136 so that a user can grasp and remove the filter. It can help lift the assembly 1111 out of the annular outer section.

In turn, that portion of the surface of cradle 1104 that extends beyond inner wall 1109 of the upper section to the inner surface of outer casing 1101 provides filter seat 1138 on which filter assembly 1118 can be supported. A lower filter seat element 1139 is then provided around the periphery of the lower end of the inner wall 1109 , and this lower end of the inner wall 1109 is received in a recess formed in the upper surface of the cradle 1104 . Accordingly, the lower filter seal element 1139 contacts and forms a seal with the bottom end cap 1135 of the filter assembly 1111 when the filter assembly 1111 is supported on the filter seat 1138 to prevent the filter assembly 1111 from Prevent air leakage around the bottom. In the illustrated embodiment, the lower filter seal element 1139 is annular and is conveniently formed from a rubber material. The inner wall 1109 of the upper section is then also provided with a plurality of ribs/segments 1140 projecting radially outwardly from the lower end of the inner wall 1109 above the lower filter sealing element 1139, these projecting segments 1140 each have a tapered/sloping outer surface to help align the filter assembly 1111 concentrically about the inner wall 1109 .

When the filter assembly 1111 is placed in the outer compartment of the body 1100, the air drawn into the body 1100 by the impeller 1110 first encounters the sidewalls of the outer casing 1101 before passing through the filter assembly 1111. It passes through an air inlet 1103 in the body 1100 provided by an aperture. This filtered air then passes through an inner compartment air inlet 1112 provided by an aperture provided in the lower portion of the inner wall 1109 and then through an air inlet 1115 provided in the bottom of the impeller housing 1114. Enters the annular air flow path of impeller housing 1114 . This air then exits the impeller housing 1114 through an air outlet 1116 provided at the top of the impeller housing 1114 before exiting the main body 1100 of the fan assembly 1000 through a vent 1123 provided by a nozzle seat 1121. Ejected.

As described above and as shown in FIGS. 4 and 6, nozzle 1200 is configured to be removably attached to fan body 1100 . Accordingly, Figures 12-15 illustrate one embodiment of a nozzle 1200 that can be removably attached to the fan body 1100 described above. 12 shows a cross-sectional side view of nozzle 1200, FIG. 13 shows a cross-sectional front view of nozzle 1200, FIG. 14 shows a cross-sectional rear view of nozzle 1200, and FIG. 15 is an isometric view of the lower end of nozzle 1200. indicate. The nozzle 1200 includes an air inlet 1202 arranged to receive airflow from the fan body 1100 , a first flow vectoring air outlet 1203 for emitting the airflow from the nozzle 1200 , and emitting the airflow from the nozzle 1200 . and a nozzle body 1201 that at least partially defines a second flow vectoring air outlet 1204 for providing. The nozzle 1200 further includes both a nozzle holding mechanism for detachably holding the nozzle 1200 on the fan body 1100 and a driven portion of the vibration mechanism. ), and a driven member 1205 arranged to be driven by the driving member 1130 for rotation about.

The first and second flow vectoring air outlets 1203, 1204 are oriented in a converging direction such that the emitted airflow converges. In other words, the first and second flow vectoring air outlets 1203 , 1204 are such that the first exiting airflow emitted from the first flow vectoring air outlet 1203 is emitted from the second flow vectoring air outlet 1204 . directed to impinge on a second exiting airflow. The nozzle 1200 further comprises an internal air passageway 1206 extending between the air inlet 1202 and both the first and second flow vectoring air outlets 1203,1204. Accordingly, a first outgoing air flow emitted from first flow vectoring air outlet 1203 and a second outgoing air flow emitted from second flow vectoring air outlet 1204 each pass through air inlet 1202 . at least a portion of the incoming airflow entering the nozzle 1200. The nozzle 1200 then further comprises a valve for controlling the flow of air from the air inlet 1202 to the first and second flow vectoring air outlets 1203, 1204, which is the first flow vectoring air outlet. A moveable valve member 1207 is provided for adjusting the size of the air outlet 1203 and inversely adjusting the size of the second flow vectoring air outlet 1204 .

By varying the size (i.e. aperture area) of the first flow vectoring air outlet relative to the size of the second flow vectoring air outlet 1204, the first and second flow vectoring air outlets 1203, 1204 also change, resulting in a change in the profile of the airflow generated by the nozzle. In particular, because the first and second flow vectoring air outlets 1203, 1204 are directed in a converging direction, the airflows emitted from the first and second flow vectoring air outlets 1203, 1204 collide and the nozzles Forming a single combined airflow that is directed away from 1200 . The angle or vector at which the composite airflow is projected from the nozzle strongly depends on the relative strengths of the first and second airflows. Therefore, by moving the valve member to adjust the size of the first flow vectoring air outlet relative to the second flow vectoring air outlet 1204, by varying their individual strengths, the combined airflow It is possible to change the direction of This arrangement means that the system is subject to a constant load, as the overall size of the collective air outlets remains constant. This means that if the airflow emitted from the nozzle 1200 can be controlled and directed back and forth, the operating point of the compressor or other means supplying the airflow to the nozzle 1200 will also remain constant. means. In addition, this allows the overall system pressure to be reduced, making the system more energy efficient and quieter.

In the illustrated embodiment, the nozzle body 1201 has the general shape of a cut sphere, with a first cut forming the circular face 1208 of the nozzle and a second cut forming the circular base 1209 of the nozzle body 1200 . be done. The air inlet 1202 of the nozzle 1200 is provided at the base 1209 of the nozzle 1200, while the first flow vectoring air outlet 1203 and the second flow vectoring air outlet 1204 are diametrically opposed on the face 1208 of the nozzle 1200. , and is oriented generally toward the central axis (Y) of face 1208 of nozzle 1200 . The angle (α) of the face 1208 of the nozzle 1200 with respect to the base 1209 of the nozzle 1200 is acute such that the first flow vectoring air outlet 1203 is closer to the second flow vectoring air outlet 1204 than the second flow vectoring air outlet 1204 on the face 1208 of the nozzle 1200. fixed to be higher. In the illustrated embodiment, this angle (α) is about 35 degrees, but the angle of surface 1208 of nozzle 1200 relative to base 1209 can be anywhere from 0 to 90 degrees, more preferably from 0 to 45 degrees, Even more preferably, it is 20 to 40 degrees.

In the illustrated embodiment, nozzle body 1201 comprises an outer casing 1210 that defines a truncated sphere. Outer casing 1210 in turn defines a circular opening 1211 on circular face 1208 of nozzle 1200 and a circular opening 1212 in circular base 1209 of nozzle 1208 . In particular, nozzle body 1201 includes a lip 1213 extending inwardly from an edge of outer casing 1210 forming a first cut. The lip 1213 is generally frusto-conical in shape and tapers inwardly toward the center of the circular surface 1208 .

Nozzle body 1201 further comprises an internally disposed inner casing 1214 that defines a single internal air passageway 1206 for nozzle 1200 . The inner casing 1214 has a circular opening at its lower end that is concentrically located within the circular opening of the outer casing at the base 1208 of the nozzle 1200 , and this lower circular opening of the inner casing 1214 opens into the main body 1100 . An air inlet 1202 is provided for receiving an air flow from. Inner casing 1214 also has a circular opening at its upper end that is positioned concentrically with outer casing circular opening 1211 in face 1208 of nozzle 1200 . The inwardly curved upper end of the inner casing 1214 then meets/abuts a lip 1213 that tapers inwardly from the outer casing 1210 to define a circular opening 1211 in the circular face 1208 of the nozzle 1200 . .

The rear portion 1214a of the inner casing 1214 then extends between the air inlet 1202 and the first flow vectoring air outlet 1203, while the opposite front portion 1214b of the inner casing 1214 extends between the air inlet 1202 and the first flow vectoring air outlet 1203. 2 flow vectoring air outlets 1204 . The rearward and forward portions 1214a, 1214b of the inner casing 1214 are such that the cross-sectional area of the internal air passage 1206 in a plane parallel to either the face 1208 or the base 1209 of the nozzle body 1201 is defined by the air inlet 1202 and the flow vectoring air outlets 1203, 1204. It is curved to vary between In particular, the aft and forward portions 1214a, 1214b of the inner casing 1214 flare or flare outwardly away from each other near the air inlets 1202 and then toward each other near the flow vectoring air outlets 1203, 1204. narrows toward Accordingly, the cross-sectional area of the air passageway 1206 increases as the air passageway 1206 extends from the air inlet 1202 until it reaches a maximum value between the air inlet 1202 and the flow vectoring air outlets 1203, 1204, and then the inner air passageway. 1206 decreases as it approaches the flow vectoring air outlets 1203,1204. As a result, the aft and forward portions 1214a, 1214b of the inner casing 1214 generally conform to the shape of the nozzle body 1201 to optimize space utilization within the outer casing 1210, and flow vectoring air outlets 1203 from air inlets 1202. , 1204 to provide a smooth transition for the airflow. As used herein, the term "curved" refers to a surface that deviates from planarity in a smooth, continuous manner.

The inner casing 1214 then comprises opposing first and second stepped side portions 1214c, 1214d, each having a side wall and an upturned wall (i.e., substantially perpendicular to the forward and rearward portions 1214a, 1214b). part). Accordingly, the first and second side walls of the inner casing 1214 are substantially flat, with the side walls of the internal air passage 1206 being substantially parallel to the plane that bisects the first and second air outlets 1203,1204. Form. In turn, the first and second upwardly facing walls of inner casing 1214 form ledges extending away from opposite sides of internal air passage 1206 toward adjacent portions of outer casing 1210 such that inner casing 1214 The upper end of the defines a generally disc-shaped cavity beneath the inwardly curved upper end. The first and second upwardly facing walls are substantially flat and substantially parallel to the circular opening 1211 provided at the upper end of the inner casing 1214 .

In turn, the first stepped side portion 1214c of the inner casing 1214 further comprises a first side duct 1215 extending radially outwardly away from the internal air passage 1206 and a second stepped side portion 1214c of the inner casing 1214. Side portion 1214 d further includes a second side duct 1216 extending radially outward away from internal air passageway 1206 in the opposite direction. Accordingly, the first side duct 1215 and the second side duct 1216 are diametrically opposed to each other and perpendicular to the plane that bisects the first and second air outlets 1203,1204. Specifically, first side duct 1215 and second side duct 1216 were each provided below an inlet opening provided in the corresponding side wall and a circular opening 1211 in face 1208 of nozzle 1200. channels sloping upwards to a disk-shaped cavity and outlet openings or side air outlets 1217 in corresponding upwardly facing walls located below the inwardly curved upper end of the inner casing 1214; 1218.

Inner casing 1214 further comprises a pair of vanes 1219 positioned within internal air passage 1206 to straighten airflow entering nozzle 1200 through air inlet 1202 of nozzle body 1201 . placed. The vanes 1219 are flat and generally parallel to a plane that bisects the first and second flow vectoring air outlets 1203, 1204, and are internally spaced between the first and second flow vectoring air outlets 1203, 1204. An air passageway 1206 extends from adjacent the air inlet 1202 to adjacent the first and second flow vectoring air outlets 1203, 1204, respectively. In other words, the vanes 1219 extend across the width of the internal air passage 1206 as well as across most of the depth of the internal air passage 1206 and extend across most of the cross-sectional area of the internal air passage 1206 .

In the illustrated embodiment, the inner casing 1214 further comprises a spindle 1220 forming another part of the slide/journal bearing assembly described above. Specifically, the spindle 1220 is positioned in the center of the lower circular opening 1212 of the inner casing 1214 (i.e., in the center of the air inlet 1202 of the nozzle 1200) and thus aligned with the vibration axis (X) of the nozzle 1200. there is The spindle 1220 is configured to fit and rotate within a bearing 1122 provided at the center of the nozzle seat 1121 . In the illustrated embodiment, the spindle 1220 comprises a preferably knurled shaft or rod 1220a projecting from the inner casing 1214 and a bearing sleeve 1220b disposed over and retained on the shaft 1220a.

In the illustrated embodiment, nozzle body 1201 is disposed within internal air passage 1206 to direct airflow entering nozzle 1200 through air inlet 1202 toward air outlets 1203 , 1204 , 1217 , 1218 of nozzle 1200 . It further comprises an air inlet guide member 1221 configured as follows. Specifically, air inlet guide member 1221 has the general shape of an oblique cone and is positioned such that the narrow end or apex of air inlet guide member 1221 is proximate air inlet 1202 . The surface of the air inlet guide member 1221 is then shaped to generally follow the shape of the opposing portion of the inner casing 1214 so that the airflow entering the nozzle 1200 through the air inlet 1202 is directed to the periphery of the inner air passage 1206. guided along. In the illustrated embodiment, the spindle 1220 of the inner casing 1214 protrudes through an aperture at the narrow end of the air inlet guide member 1221 .

The valve member 1207 is then adjacent the circular opening 1211 in the circular surface 1208 of the nozzle 1200 (i.e., defined by the upper circular opening of the outer casing 1210 and the upper circular opening of the inner casing 1214), Located within nozzle body 1201 . Specifically, valve member 1207 is disposed within a cavity defined by the upper end of inner casing 1214 .

Figures 16, 17 and 18 illustrate one embodiment of a valve member 1207 suitable for use with the nozzles 1200 described herein. 16 shows an isometric front view of valve member 1207, FIG. 17 shows an end-facing view of valve member 1207, and FIG. 18 shows a cross-sectional side view of valve member 1207. FIG. In the illustrated embodiment, valve member 1207 has a generally circular front cross-section and includes upper section 1222 and lower section 1223 . The outermost/uppermost surface of upper section 1222 is generally convex (ie, bulges outward) and is exposed within opening 1211 provided in face 1208 of nozzle 1200 . As used herein, the term "convex" means an outwardly bulging surface, thus having a curved convex shape or a convex polygonal shape composed at least partially of straight lines. can have a shape. As a result, the outermost/top surface of upper section 1222 forms the outer surface of nozzle body 1201 . The innermost/lowermost surface of the lower section 1223 is also generally convex and is positioned within the nozzle body 1201 such that its innermost/lowermost surface faces the internal air passageway 1206 . Thus, the innermost/lowermost surface of the lower section 1223 forms the inner surface of the nozzle body 1201 and the convex shape of the innermost/lowermost surface directs airflow within the internal air passage 1206 to the outer periphery of the valve member 1207. It assists in directing towards the first and second flow vectoring air outlets 1203, 1204 provided.

Next, on the innermost/lowermost surface of the lower section 1223 , the valve member 1207 is positioned within the nozzle body 1201 laterally (i.e., laterally) to the opening 1211 provided in the face 1208 of the nozzle body 1201 . , left and right) and over a range of positions between a first end position and a second end position. A pair of grooves/tracks 1224 forming a part are provided. These grooves/tracks 1224 are configured to fit over the upper portions of the air directing vanes 1219 when the valve member 1207 is positioned within the nozzle body 1201 . Thus, the upper portion of air baffle vanes 1219 provide rails that are positioned within grooves/tracks 1224 provided on the innermost/lowermost surface of valve member 1207 and thus provide another part of the sliding mechanism. As a result, both vanes/rails 1219 and corresponding grooves/tracks 1224 are parallel to the plane that bisects the first and second flow vectoring air outlets 1203, 1204, allowing the first and second flow It extends across the internal air passageway 1206 in a direction extending between the vectoring air outlets 1203,1204.

In the illustrated embodiment, the sliding mechanism of nozzle 1200 resists movement of valve member 1207 relative to nozzle body 1201, thereby maintaining the position of valve member 1207 when no external force is applied to valve member 1207. (ie, to resist movement of valve member 1207 when the only applied force is gravity). Thus, the resistance provided by brake 1225 is sufficient to hold the position of valve member 1207 when no external force is applied, but can be easily overcome by user applied/manual force. For example, a user can place a hand on the outermost/top surface of the valve member 1207 and push or pull the valve member 1207 toward either the rear or front of the nozzle body 1201 to easily overcome the resistance. be able to. Each brake 1225 comprises a friction pad/member 1225a and a resilient member 1225b (eg, a compression spring) configured to bias the friction pad 1225a against the braking surface 1225c. Specifically, each brake 1225 is configured such that the direction in which the resilient member 1225b biases the friction pad 1225a is substantially orthogonal/perpendicular to the direction in which the valve member 1207 is configured to move within the nozzle body 1207. configured to In the illustrated embodiment, each brake 1225 is attached to valve member 1207 and braking surface 1225 c is provided by a portion of inner casing 1214 . Accordingly, the valve member 1207 is provided with a pair of brake seats 1225d, wherein the resilient member 1225b of each brake 1225 is positioned between the corresponding seat 1225d and the friction pad/member 1225a to provide a friction pad/member. configured to bias 1225a toward valve member 1207; Each brake seat 1225 d is provided by a projection extending from the valve member 1207 and through a corresponding aperture/slot provided in one of the upwardly facing walls of the inner casing 1214 . Thus, for each brake 1225, the resilient member 1225b biases the friction pad/member 1225a against the portion of the lower surface of the upward facing wall of the inner casing 1214 located opposite the slot.

The first flow vectoring air outlet 1203 is then connected to the rim first portion 1211a of the circular opening 1211 in the face 1208 of the nozzle 1200 and the valve member 1207 adjacent the rim first portion 1211a. second flow vectoring air outlet 1204 is defined by a first portion 1207a of the outermost/top surface of the nozzle 1200 and a second portion 1211b of the edge of opening 1211 in face 1208 of nozzle 1200; and the outermost/uppermost second portion 1207b of the valve member 1207 adjacent the second portion 1211b of the portion. Accordingly, the first and second flow vectoring air outlets 1203, 1204 comprise a pair of diametrically opposed curved slots within a circular opening 1211 defined by the nozzle body 1201 in the face 1208 of the nozzle 1200 and valve The outermost/top surface of member 1207 extends between first and second flow vectoring air outlets 1203,1204.

In the illustrated embodiment, the first and second flow vectoring air outlets 1203, 1204 comprise a pair of congruent arcuate slots each having an arc angle (β) of approximately 60 degrees (i.e. but they can each have an arc angle anywhere from 20 to 110 degrees, preferably from 45 to 90 degrees, more preferably from 60 to 80 degrees. The first and second flow vectoring air outlets 1203, 1204 also direct the emitted airflow over a portion of the outermost/top surface of the valve member 1207 adjacent to the corresponding air outlets. be done. As a result, the outermost/topmost surface of valve member 1207 provides an outer guiding surface for nozzle body 1201 .

As described above, the sliding mechanism of the valve allows the valve member 1207 to slide laterally within the nozzle body 1201 through a range of positions between the first end position and the second end position. can. The valve is then positioned within the nozzle body 1201 such that movement of the valve member 1207 adjusts the size of the first flow vectoring air outlet 1203 and at the same time adjusts the size of the second flow vectoring air outlet 1204 inversely. placed in In particular, the valve member 1207 is such that the first flow vectoring air outlet 1203 is maximally open (i.e., the size of the first flow vectoring air outlet 1203) when the valve member 1207 is in the first end position. is maximally possible) and the second flow vectoring air outlet 1204 is maximally occluded (i.e., so that the size of the second flow vectoring air outlet 1204 is minimal , to the maximum extent possible) and when the valve member 1207 is in the second end position, the first flow vectoring air outlet 1203 is maximally occluded and the second flow vectoring air outlet is closed. It is positioned within nozzle body 1207 such that 1204 is maximally open. In other words, the size of the first flow vectoring air outlet 1203 is largest when the valve member 1207 is in the first end position and smallest when the valve member is in the second end position. In contrast, the size of second flow vectoring air outlet 1204 is smallest when valve member 1207 is in the first end position and largest when valve member 1207 is in the second end position. Specifically, when in the first end position, the second portion 1207b of the valve member 1207 (i.e., the portion that partially defines the second flow vectoring air outlet 1204) defines the second flow vectoring air outlet. When 1204 is maximally occluded and in the second end position, first portion 1207a of valve member 1207 (i.e., the portion that partially defines first air outlet 1203) provides a first flow vectoring. The air outlet 1203 is maximally occluded.

Further, the aggregate/combined size of the first and second flow vectoring air outlets 1203, 1204 is kept constant as the valve member 1207 moves between the first and second end positions. 1207a of valve member 1207 (i.e., the portion that partially defines first flow vectoring air outlet 1203) and a plane parallel to opening 1211 in face 1208 of nozzle 1200. The angle defined between the first portion 1207a of the valve member 1207 (i.e., the portion that partially defines the first flow vectored air outlet 1203) and the plane parallel to the opening 1211 in the face 1208 of the nozzle 1200. is defined between second portion 1207b of valve member 1207 (i.e., the portion that partially defines second flow vectoring air outlet 1204) and opening 1211 in face 1208 of nozzle 1200. Approximately equal to the angle defined between parallel planes. In this regard, the first and second portions 1207a, 1207b of the valve member 1207 can be flat or slightly curved. When curved, the angle subtended by first portion 1207a and second portion 1207b, respectively, is the angle of the chord of the curve, where a chord is the line segment connecting two points on the curve. The angular coincidence ensures that the first and second flow vectoring air outlets 1203, 1204 open and close at the same rate when the valve member 1207 is moved laterally, thus the first and second flow vectoring The aggregate size of air outlets 1203 , 1204 is substantially constant regardless of the position of valve member 1207 .

In the illustrated embodiment, the valve member 1207 is such that the size difference between the first flow vectoring air outlet 1203 and the second flow vectoring air outlet 1204 when the valve member 1207 is in the first end position is equal to the valve It is configured to be greater than the size difference between the first flow vectoring air outlet 1203 and the second flow vectoring air outlet 1204 when the member 1207 is in the second end position. Specifically, the first flow vectoring air outlet 1203 when the valve member 1207 is in the first end position (i.e., when the first flow vectoring air outlet 1203 is fully apertured). is the size of second flow vectoring air outlet 1204 when valve member 1207 is in the second end position (i.e., when second flow vectoring air outlet 1204 is fully apertured). and the first flow vectoring air outlet 1203 when the valve member 1207 is in the second end position (i.e., when the first flow vectoring air outlet 1203 is maximally occluded). The size of 1203 is such that the second flow vectoring air outlet 1204 when the valve member 1207 is in the first end position (i.e., when the second flow vectoring air outlet 1204 is maximally occluded). larger than the size of

This configuration results in the vectoring range of the airflow generated by the nozzle 1200 being biased towards the second flow vectoring air outlet 1204 provided towards the face of the nozzle 1200, which is the fan assembly. If the volume 1000 is intended to provide a combined airflow to a single user, especially if the fan assembly 1000 is placed on an elevated surface such as a table or desk next to the user. It is particularly advantageous. To achieve some of this bias, the valve member 1207 is provided with valve end stops 1226, 1227 positioned to limit movement of the valve member 1207 beyond proper end positions. In the illustrated embodiment, the valve member 1207 protrudes from a first portion 1207a of the outermost/topmost surface of the valve member 1207 (i.e., the portion that partially defines the first flow vectoring air outlet 1203). A first pair of valve end stops 1226 and a valve end stop projecting from the outermost/uppermost second portion 1207b of the valve member 1207 (i.e., the portion that partially defines the second flow vectoring air outlet 1204) A second pair 1227 of are provided. The first pair of valve end stops 1226 are arranged to abut a portion of the inner casing 1214 adjacent the first flow vectoring air outlet 1203 when in the second end position, whereas the valve end stops 1226 A second pair of end stops 1227 are positioned to abut a portion of the inner casing 1214 adjacent the second flow vectoring air outlet 1204 when in the first position. The distance that the first pair of valve end stops 1226 extends from the valve member 1207 is less than the distance that the second pair of valve end stops 1227 extends from the valve member 1207, so that when the valve member 1207 is in the second end position The size of the first flow vectoring air outlet 1203 is larger/wider than the size of the second flow vectoring air outlet 1204 when the valve member 1207 is in the first end position. In the illustrated embodiment, both the first pair of valve end stops 1226 and the second pair of valve end stops 1227 are a pair of planar plates that extend away from the edge of the valve member 1207 at opposite ends of the valve member 1207 . Provided by a protrusion. Accordingly, these planar protrusions assist in directing air discharged from the first and second flow vectoring air outlets 1203, 1204 in a converging direction above the outermost/topmost surface of the valve member 1207. It can also function as a baffle.

In the illustrated embodiment, the outermost/top surface of valve member 1207 also has an asymmetrical profile/cross-section. In particular, the valve member 1207 is such that the depth (Da) of the outermost/topmost surface of the valve member 1207 at the first portion 1207a (i.e., the portion that partially defines the first flow vectoring air outlet 1203) is 2 (ie, the portion that partially defines the second flow vectoring air outlet 1204) has a profile that is less than the outermost/topmost surface depth (Db). As a result, the valve is such that, in a direction perpendicular to the opening 1211 and the lateral movement of the valve member 1207, the minimum distance between the edge of the opening 1211 and the outermost/uppermost surface of the valve member 1207 is the first flow. The vectoring air outlet 1203 is configured to be larger than the second flow vectoring air outlet 1204 . In this regard, the minimum distance at the first flow vectoring air outlet 1203 is the first portion 1211a of the edge of the opening 1211 and the valve member 1207 when the valve member 1207 is in the second end position. is the distance to the first portion 1207a of the outermost/topmost surface of the second flow vectoring air outlet 1204, and the minimum distance at the second flow vectoring air outlet 1204 is the distance from the opening 1211 when the valve member 1207 is in the first end position. is the distance between a second portion 1211b of the edge of the valve member 1207 and a second portion 1207b of the outermost/uppermost surface of the valve member 1207; This asymmetry causes the vectoring extent of the airflow generated by the nozzle 1200 to be biased toward the second flow vectoring air outlet 1204 provided toward the face of the nozzle 1200, because the second This is because the minimum airflow emitted from one flow vectoring air outlet 1203 is greater than the minimum airflow emitted from the second flow vectoring air outlet 1204 . In addition, this asymmetry allows maximizing the lateral range of travel of the valve member 1207 for desired changes in the size of the first and second flow vectoring air outlets 1203, 1204, which increases the granularity of control available to the user. A suitable asymmetric profile can be achieved by taking a symmetrical profile and simply trimming one end of the profile because doing so makes one portion of the valve member 1207 shorter than the other. , as the valve member 1204 moves between the first and second end positions, since the angles of the two portions with respect to the opening 1211 (as well as with respect to the direction of motion of the valve member 1207) remain equal, This is because the aggregate/combined size of the first and second flow vectoring air outlets 1203, 1204 is guaranteed to be constant.

As previously described, the inner casing 1214 includes a first side duct 1215 extending radially outwardly away from the internal air passage 1206 and sloping upwardly toward a circular opening in the face 1211 of the nozzle 1200. and diametrically opposed second side ducts 1216 . The side ducts 1215 , 1216 thus channel a portion of the airflow from within the internal air passage 1206 through their corresponding outlet openings or sides facing into the generally disc-shaped cavity defined by the upper end of the inner casing 1214 . to the two air outlets 1217,1218. The nozzle 1200 then directs any airflows emitted from these side air outlets 1217, 1218 to a point where the airflows emitted from the first and second flow vectoring air outlets 1203, 1204 converge. configured to guide toward In this regard, these side air outlets 1217 , 1218 are configured to discharge only a relatively small portion of the airflow generated by the motor driven impeller 1210 . In turn, the relatively small jets of air emitted from the side air outlets 1217, 1218 assist the impingement of the air streams emitted from the flow vectoring air outlets 1203, 1204, thereby increasing the flow vectoring air outlets. It provides an increase in the velocity of the composite airflow produced by the nozzle 1200 without significantly reducing the airflow through 1203,1204.

In the illustrated embodiment, the nozzle 1200 is capable of discharging approximately 12.5% of the total airflow generated by the motor driven impeller 1210 through the side air outlets 1217, 1218, while the remaining airflow is , are emitted from the flow vectoring air outlets 1203, 1204 of the nozzle 1200 used to provide variable control over the direction of the resultant airflow. As a result, the area of each of the side air outlets 1217, 1218 is approximately 6.25% of the total area of the outlets provided by the nozzle 1200, which is the area of the two side air outlets 1217, 1218. The combined area and the total area of the flow vectoring air outlets 1203 , 1204 of the nozzle 1200 . However, the area of each of the side air outlets 1217, 1218 may be larger or smaller. For example, the area of each of the side air outlets 1217, 1218 can be between 12.5% and 4% of the total area of the outlets provided by the nozzle 1200.

In the illustrated embodiment, the valve member 1207 is also provided with diametrically opposed first and second flange portions 1228 , 1229 projecting radially outwardly from the periphery of the valve member 1207 . Each of these first and second flange portions 1228, 1229 includes a slot or aperture 1230, 1231 which directs air discharged from the first and second flow vectoring air outlets 1203, 1204. Positioned above/aligned with the side air outlets 1217, 1218 of the corresponding side ducts 1215, 1216 when the valve member 1206 is in a substantially equal flow position, and the valve member 1207 is positioned in this position. are configured to be displaced away from the side air outlets 1217, 1218 of the corresponding side ducts 1215, 1216 when moving away from the . As a result, the size of the side air outlets 1217, 1218 depends on the position of the valve member 1207, and movement of the valve member 1207 simultaneously adjusts the size of the side air outlets 1217, 1218. Specifically, the first and second flange portions 1228, 1229 maximize the side air outlets 1217, 1218 when the size of the first air outlet 1203 is approximately equal to the size of the second air outlet 1204. It is configured to be open and maximally occluded/closed when the size difference between the first flow vectoring air outlet 1203 and the second flow vectoring air outlet 1204 is greatest. As will be described in more detail below, in the illustrated embodiment, the size of the first air outlet 1203 is approximately equal to the size of the second air outlet 1204 when the valve member 1207 is in the second end position. , the size difference between the first flow vectoring air outlet 1203 and the second flow vectoring air outlet 1204 is greatest when the valve member 1207 is in the first end position. The valve member 1207 in turn further comprises a pair of side baffles 1232,1233 for each slot 1230,1231 which direct air discharged from the corresponding side air outlets 1217,1218 to the valve member. It is configured to help flow in a converging direction above the outermost/topmost surface of 1207 .

As mentioned above, the nozzle 1200 is removably attached to the fan body 1100 and thus removable from the fan body 1100 . Accordingly, the nozzle 1200 has a nozzle holding mechanism for detachably holding the nozzle 1200 to the fan body 1100 . The nozzle retention mechanism has a first configuration in which nozzle 1200 is retained in fan body 1100 and a second configuration in which nozzle 1200 is released for removal from fan body 1100 . The nozzle retention mechanism is also arranged to be biased toward the first configuration so that the nozzle retention mechanism will retain the nozzle 1200 to the fan body 1100 unless the user places it in the second configuration.

In the illustrated embodiment, nozzle 1200 includes a pair of nozzle retention features 1234 , 1235 diametrically opposed within nozzle body 1201 . These nozzle retention mechanisms 1234 , 1235 are located in the space defined between the side portions of the inner casing 1214 and the outer casing 1210 of the nozzle body 1201 . Each of these nozzle retention mechanisms 1234, 1235 comprises a catch-shaped retention element 1234a, 1235a movable relative to the nozzle 1200 and fan body 1100 between first and second configurations. Each of these nozzle retention mechanisms in turn further comprises a manually actuatable member 1234b, 1235b to effect movement of the retention elements 1234a, 1235a from the first configuration to the second configuration. Specifically, each manually actuatable member 1234b, 1235b takes the form of a depressible button that projects into a corresponding aperture provided in the outer casing 1210 of the nozzle body 1201 such that these depressible A button is available to the user to actuate the movable catches 1234 a, 1235 a to release the nozzle 1200 from the fan body 1100 .

Specifically, for each nozzle retention mechanism, depressible buttons 1234b, 1235b and moveable catches 1234a, 1235a are formed as a single component latch that is pivotally mounted within outer casing 1210 of nozzle body 1201. and depressible buttons 1234b, 1235b are provided at one end and catches 1234a, 1235a are provided at the other end. A biasing member 1234c, 1235c in the form of a compression spring is then positioned between the underside of the depressible button 1234b, 1235b and the inner portion of the nozzle body 1201 to force the latch toward the outer casing 1214 into the first configuration. energize. Thus, applying pressure to the depressible buttons 1234b, 1235b against the force of the compression springs 1234c, 1235c pivots the latches and the catches 1234a, 1235a engage the second to remove the nozzle 1200 from the fan body 1100. It is designed to move to two configurations. As previously mentioned, the nozzle seat 1121 of the fan body 1100 has a radially inwardly projecting ledge/lip 1128 that partially overhangs the arcuate recess 1127 . Accordingly, the nozzle retention mechanism is such that when the nozzle 1200 is positioned on the fan body 1100 with the nozzle retention mechanism in the first configuration, the catches 1234a, 1235a are obstructed by this ledge 1128, thereby allowing the body of the nozzle 1200 to move. The catches 1234a, 1235a are kept away/obstructed from this ledge 1128 so that separation from 1100 is prevented and when the nozzle 1200 is positioned on the fan body 1100 with the nozzle retention mechanism in the second configuration. It is provided such that it allows the nozzle 1200 to be separated from the body 1100 .

As previously mentioned, the nozzle 1200 further comprises a driven portion of a vibrating mechanism, the driven portion arranged to be driven by the drive member 1130 to rotate the nozzle body 1201 about the vibration axis (X). A driven member 1205 is provided. In the illustrated embodiment, the driven member 1205 comprises an at least partially circular or arcuate rack that, when the nozzle 1200 is positioned on the fan body 1100, provides the drive member for the vibratory mechanism. is provided to engage a pinion 1130 on the fan body 1100 that Specifically, rack 1205 includes a set of teeth positioned to mesh with teeth provided on pinion 1130 when nozzle 1200 is positioned on fan body 1100 . In the embodiment shown in FIG. 9, rack 1205 comprises a spool rack having a plurality of radially projecting teeth that are linear and aligned parallel to the axis of rotation (X), but the edges of the lower portion of rack 1205 are aligned parallel to the axis of rotation (X). is chamfered. Specifically, both the roots and teeth of the lower portion of rack 1205 are chamfered, and the angle of the chamfered roots is preferably about 45 degrees. Thus, the chamfered upper portion of pinion 1130 and the chamfered lower portion of rack 1205 ensure proper engagement between rack 1205 and pinion 1130 when nozzle 1200 is mounted on fan body 1100. This assists in that meshing while minimizing the risk of possible damage if the teeth collide.

As previously mentioned, in the illustrated embodiment, the pinion 1130 is positioned radially outwardly with respect to the annular vent 1123 of the fan body 1100 . Rack 1205 is thus positioned radially outwardly relative to air inlet 1202 of nozzle body 1201 . Specifically, the rack 1205 is mounted on the peripheral surface of the inner casing 1214 toward the lower end of the inner casing (i.e., adjacent to the air inlet into the internal air passage), the teeth of the rack and protrudes radially outward.

Nozzle 1200 then further comprises a pair of nozzle stops 1236, 1237 provided on nozzle body 1201, each of which rotates nozzle body 1201 beyond the ends of its oscillation range. placed to prevent In particular, first nozzle stop 1237 is positioned to prevent nozzle body 1201 from rotating beyond a first end of its vibration range, and second nozzle stop 1237 is positioned to prevent nozzle body 1201 from rotating beyond its vibration range. positioned to prevent rotation beyond a second end opposite the . In the illustrated embodiment, the first nozzle stop 1236 is provided by a first projection extending radially outwardly from the inner casing 1214 of the nozzle 1200, the projection locating the nozzle body 1201 at a first end of its range of vibration. is arranged to contact/abut a corresponding portion of the fan body 1100 when reaching a point. A second nozzle stop 1237 is then provided by a second projection extending radially inwardly from the inner casing 1214 of the nozzle 1200 until the nozzle body 1201 reaches a second end of its range of vibration. They are arranged to contact/abut corresponding portions of the fan body 1100 at times. Specifically, the first nozzle stop 1236 is positioned to abut a first side of the raised portion of the nozzle seat 1121 when the nozzle body 1201 reaches the first end of its oscillation range, A two-nozzle stop 1237 is positioned to abut a second side of the nozzle seat 1121 opposite the raised portion when the nozzle body 1201 reaches the second end of the oscillation range.

The first and second nozzle stops 1236, 1237 also prevent the nozzle 1200 from being attached to the fan body 1100 when the nozzle body 1201 is oriented relative to the fan body 1100 outside the range of vibration of the nozzle body 1201. placed to hinder Therefore, the first and second nozzle stops 1236, 1237 are designed to prevent the nozzle seat 1200 from falling toward the fan body 1100 while the nozzle body 1201 is oriented out of the vibration range with respect to the fan body 1100. 1121 is positioned to contact the upper surface of the raised portion of 1121, thereby preventing the nozzle 1200 from coming close enough to the fan body 1100 for the nozzle retention features 1234, 1235 to engage the fan body 1100. Specifically, the first nozzle stop 1236 is designed to prevent the nozzle 1200 from falling toward the fan body 1100 while the nozzle body 1201 is oriented beyond the first end of the vibration range relative to the fan body 1100 . , and a second nozzle stop 1237 is positioned to contact the upper surface of the raised portion of the nozzle seat 1121 while the nozzle body 1201 is oriented with respect to the fan body 1100 beyond the second end of the vibration range. When the nozzle 1200 descends toward the fan body 1100, it is arranged so as to contact the upper surface of the raised portion of the nozzle seat 1121. As shown in FIG.

Next, the nozzle 1200 further comprises complementary parts of the orientation detection mechanism. As described above, the fan body 1100 is provided with the photointerrupter 1131 as part of the mechanism for detecting the orientation of the nozzle body 1201 when the nozzle 1200 is attached to the fan body 1100 . In the illustrated embodiment, a complementary component of the orientation detection mechanism provided on the nozzle body 1201 comprises an at least partially circular/arcuate partition/shield plate 1238 depending/protruding from the nozzle body 1201, which partition/shield plate is , is detected by the photointerrupter 1131 when the nozzle body 1201 is in one of the two halves of the oscillation range. Specifically, the shielding plate 1238 is positioned within the arcuate recess 1127 of the nozzle seat 1121 when the nozzle 1200 is attached to the fan body 1100 . As a result, when the nozzle body 1201 is in the first half of the two halves of the vibration range, the shield plate 1238 will be positioned within the gap between the light emitting element and the light receiving element of the photo interrupter 1131, thereby preventing the light from the light emitting element from of light from reaching the light receiving element. When the nozzle body 1201 is in the second half of the oscillation range, the shield 1238 will move away from the gap so that light from the light emitting element reaches the light receiving element.

Photointerrupter 1131 is provided to provide its output as an input to control circuit 1106 . Control circuit 1106 is then configured to control vibration motor 1129 using input from photointerrupter 1131 . Specifically, initially, the input received from photointerrupter 1131 is either gap closed and thus nozzle body 1201 is in the first half of both halves of the oscillation range, or gap is open and thus This will indicate whichever nozzle body 1201 is in the second half of the oscillation range. Control circuit 1106 is then configured to operate vibration motor 1129 such that nozzle body 1201 rotates toward the midpoint of the vibration range. Upon reaching the midpoint, the edge of shield plate 1238 passes through the gap, causing photointerrupter 1131 to transition between a blocked state and an open state, which causes control circuit 1106 to cause nozzle body 1206 to is at the midpoint of the vibration range. Control circuit 1106 then applies a rotational distance limit (eg, defined by the number of steps used by the stepper motor) and/or a time limit to limit the rotation of nozzle body 1201 within the oscillation range. to control the vibration motor 1129.

Nozzle 1200 further comprises a base member 1239 positioned to contact fan body 1100 when nozzle 1200 is attached to fan body 1100 . The nozzle body 1200 is arranged to be rotatable relative to the base member 1239 so that the base member 1239 can remain stationary relative to the fan body 1100 when the nozzle 1200 is attached to the fan body, The nozzle body 1201 is adapted to rotate relative to both the fan body 1100 and the base member 1239 of the nozzle body 1200 . The base member 1209 in turn includes an upper filter seal element 1239a that, when the nozzle 1200 is attached to the fan body 1100, the upper filter seal element 1239a is positioned between the upper surface of the filter assembly 1111 and the fan body 1100. 1111 to prevent air leakage around the upper end of the filter assembly 1111 .

In the illustrated embodiment, base member 1239 further comprises an annular plate 1239b. In that case, the upper filter sealing element 1239a is also annular and attached to the lower surface of the annular plate 1239b. The upper filter seal element 1239a comprises two separate flap seal portions, a first projecting radially inwardly and a second extending downwardly and radially outwardly. Thus, the upper filter seal element 1239a has a first seal portion contacting and forming a seal with the upper portion of the inner wall 1109 of the fan body 1100 when the nozzle 1200 is attached to the fan body 1100, while the second seal portion is positioned to contact upper end cap 1136 of filter assembly 1111 to form a seal. Upper filter seal element 1239a is conveniently formed from a rubber material.

The nozzle body 1201 in turn further comprises a plurality of runners 1240 mounted toward the base 1209 of the nozzle body 1201 , which hold the base member 1239 while the base member 1239 is attached to the nozzle body 1201 . arranged to allow it to rotate with respect to As used herein, the term "runner" refers to a mechanical part intended to guide movement. In the illustrated embodiment, each runner 1240 comprises a groove configured to receive a portion of base member 1239 . In that case, the base member 1239 further comprises a flange/rail 1239 c arranged and configured to slide within each of the plurality of runners 1240 . In the illustrated embodiment, the flange/rail 1239c is provided on the top surface of the annular plate 1239b and projects radially with respect to the vibration axis (X) of the nozzle body 1201 .

To use the fan assembly 1000 , the user first removes the nozzle 1200 from the nozzle body 1100 . To do so, the user presses depressible buttons 1234b, 1235b of the nozzle retention mechanism available through the outer casing 1210 of the nozzle body 1201, thereby pivoting the latches and corresponding catches 1234a, 1235b to the second configuration. It is designed to move to The user then lifts the nozzle 1200 away from the fan body 1100 in a direction parallel to the longitudinal axis (X) of the fan assembly 1000, including the nozzle seat 1121 and the open top end of the outer section. to expose the upper end of the fan main body 1100 . The user then lowers the filter assembly 1111 into the outer compartment until the lower end cap 1135 rests on the filter seat 1139, with the filter assembly 1111 surrounding the entire perimeter of the inner wall 1109 of the fan body 1100.

The user then reattaches nozzle 1200 to fan body 1100 . Thus, the user roughly aligns the nozzle 1200 with the upper end of the fan body 1100 and lowers the nozzle 1200 toward the fan body 1100 . A circular opening 1212 defined by the outer casing 1210 in the circular base 1209 of the nozzle 1200 is positioned to fit closely over the upper end of the fan body 1100 so that the nozzle 1200 moves toward the fan body 1100. When doing so, the upper end of the fan body 1100 enters the circular opening 1212 first. As a result, when there is a large misalignment between the nozzle 1200 and the fan body 1100, the edge of the circular base 1209 of the nozzle 1200 collides with the edge of the upper end of the fan body 1100, causing the fan body 1100 to move. Point out to the user that the nozzle 1200 needs to be repositioned. As the upper end of the fan body 1100 moves into the circular base 1209 of the nozzle 1200, a spindle 1220 forming part of a plain bearing assembly provided in the nozzle 1200 moves a bearing centrally provided in the nozzle seat 1121. Enter the hollow of 1122. The chamfered inner edge of bearing 1122 helps guide spindle 1220 into bearing 1122 if there is misalignment between nozzle 1200 and fan body 1100 .

Further movement of the circular base 1209 of the nozzle 1200 over the upper end of the fan body 1100 causes the upper filter seal element 1239a attached to the lower surface of the annular plate 1239b to contact both the fan body 1100 and the filter assembly 1111. Specifically, a first sealing portion of upper filter seal element 1239 a contacts an upper portion of inner wall 1109 of fan body 1100 , thereby forming a seal between nozzle 1200 and inner wall 1109 of fan body 1100 . be. The second sealing portion of upper filter seal element 1239a then contacts upper end cap 1139 of filter assembly 1111 disposed within the outer compartment, thereby creating a seal between nozzle 1200 and filter assembly 1100. It is formed. The driving member 1130 of the vibrating mechanism then engages the driven member 1205 of the vibrating mechanism. Specifically, in this case, the rack 1205 provided on the nozzle 1200 meshes with the pinion 1130 provided on the fan body 1100, and both the lower edge of the rack 1205 and the upper edge of the pinion 1130 are chamfered. , the alignment of the teeth of the rack 1205 and the teeth of the pinion 1130 is assisted.

Further movement of the circular base 1209 of the nozzle 1200 over the upper end of the fan body 1100 causes the catches 1234 a , 1235 a of the retention mechanism to contact ledges 1128 provided on the nozzle seat 1121 . This contact causes the latches 1234, 1235 to pivot against the force of the corresponding compression springs 1234c, 1235c so that the catches 1234a, 1235a pass over the ledges 1128. Once the catches 1234a, 1235a leave the ledge 1128, the force of the compression springs 1234c, 1235c pivots the latches 1234, 1235 back to the first configuration such that the nozzle 1200 is retained in the fan body 1100. Also, the air inlet 1202 of the nozzle body 1201 contacts the body outlet seal member 1125 provided at the periphery of the annular vent 1123 of the nozzle body 1100, thereby connecting the fan body 1100 and the internal air passage 1206 of the nozzle 1200. Forming a seal therebetween, a nozzle alignment surface 1126 located at the periphery of the body outlet seal member 1125 guides the air inlet 1202 of the nozzle 1200 into alignment with the air outlet 1123 of the body 1100 .

The user then interacts with fan assembly 1100 (eg, using a remote control) to provide control inputs that control circuitry 1106 receives. In response to these inputs, control circuit 1106 may start motor 1119 to rotate impeller 1110 to generate airflow through fan assembly 1000 . Specifically, rotation of impeller 1110 draws air through air inlet 1103 in fan body 1100 provided by an aperture in the side wall of outer casing 1101 and then through filter assembly 1111 . The resulting filtered air is then drawn through an inner compartment air inlet 1112 provided by an aperture provided in the lower portion of the inner wall 1109 prior to an air inlet provided at the bottom of the impeller housing 1114. Enters impeller housing 1114 through 1115 . This air then exits the impeller housing 1114 through an air outlet 1116 provided at the top of the impeller housing 1114 before exiting the main body 1100 of the fan assembly 1000 through a vent 1123 provided by a nozzle seat 1121. It is expelled and enters the internal passageway 1206 of the nozzle 1200 through an air inlet 1202 provided by a lower circular opening in the inner casing 1214 of the nozzle body 1201 .

Once within the interior passageway 1206 of the nozzle 1200 , the air inlet guide member 1221 guides the airflow entering the nozzle 1200 toward the outer periphery of the interior air passageway 1206 while the vanes 1219 provided within the interior air passageway 1206 . straightens the airflow towards the air outlets 1203 , 1204 of the nozzle 1200 . The innermost/lowermost surface of the lower section of the valve member 1207 then also directs the airflow within the internal air passage 1206 of the nozzle 1200 to the first and second flow vectoring air provided at the outer periphery of the valve member 1207 . Assist in directing towards exits 1203,1204.

The first flow vectoring air outlet 1203, the second flow vectoring air outlet 1204, and the outermost/top surface of the valve member 1207 were discharged from the first and second flow vectoring air outlets 1203, 1204. Airflow is arranged to be directed over portions of the outermost surface 1207a, 1207b of the valve member 1207 adjacent the respective air outlets 1203,1204. In particular, the flow vectoring air outlets 1203,1204 are arranged to emit airflow in a direction generally parallel to that portion of the outermost surface 1207a,1207b of the valve member 1207 adjacent the air outlets 1203,1204. The convex shape of the outermost surface of the valve member 1207 then causes the airflows emitted from the first and second flow vectoring air outlets 1203, 1204 to move away from the outermost surface of the valve member 1207 as they approach each other. , so that these air streams can impinge without interference from the outermost surface of valve member 1207 . A separation bubble is formed when the ejected air streams collide, which can help stabilize the composite jet or multiple air streams formed when two opposing air streams collide.

The valve then adjusts the size of the first flow vectoring air outlet 1203 at the same time and inversely adjusts the size of the second flow vectoring air outlet 1204, thereby causing the nozzle 1200 to adjust the size of the second flow vectoring air outlet 1204, as described above. arranged to control the direction of the generated airflow. In the illustrated embodiment, the sliding mechanism of the valve causes the valve member 1207 to be fully open at the first flow vectoring air outlet 1203 and fully closed at the second flow vectoring air outlet 1204 . Over a range of positions between one end position and a second end position where the first flow vectoring air outlet 1203 is maximally occluded and the second air outlet 1204 is maximally open, the nozzle It can slide laterally within the body 1201 . 19A and 19B thus show two possible combined airflows that can be achieved by varying the size of the first flow vectoring air outlet 1203 relative to the size of the second flow vectoring air outlet 1204. there is

In FIG. 19A, the valve is positioned with the valve member 1207 in the second end position, the first flow vectoring air outlet 1203 is maximally occluded and the second flow vectoring air outlet 1204 is closed. Open to the maximum. As previously described, the vectoring range of the airflow generated by nozzle 1200 is controlled by valve end stops 1226, 1227 positioned to limit movement of valve member 1207 beyond the proper end position of nozzle 1200. It is biased towards the second flow vectoring air outlet 1204 provided towards the face. In the embodiment shown in FIG. 19A, the first pair of valve end stops 1226 provide a first flow vectoring air outlet 1203 when the first flow vectoring air outlet 1203 is approximately the same size as the second flow vectoring air outlet 1204. It is positioned to abut a portion of inner casing 1214 adjacent vectoring air outlet 1203 . As a result, since the amount of airflow emitted from both the first flow vectoring air outlet 1203 and the second flow vectoring air outlet 1204 when in the second end position is approximately equal, The resulting combined airflow is to be directed generally upward (ie, generally perpendicular to face 1208 of nozzle 1200), as indicated by arrow AA.

Further, in the illustrated embodiment, the first and second flange portions 1228, 1229 of the valve member 1207 are configured to extend toward the first flow vectoring air outlet 1203 when the valve member 1207 is in the second end position (ie, the first flow vectoring air outlet 1203). is approximately equal to the size of the second flow vectoring air outlet 1204), the side air outlets 1217, 1218 are arranged to be maximally open. As a result, a relatively small portion of the total airflow generated by the motor driven impeller 1110 is discharged through the side air outlets 1217, 1218 and through the first and second flow vectoring air outlets 1203, 1204. It will be directed over the outermost/uppermost surface of the valve member 1207 towards a point where the combined airflow converges.

In FIG. 19B, the valve is positioned with valve member 1207 in the first end position, first flow vectoring air outlet 1203 is fully open, and second flow vectoring air outlet 1204 is fully open. maximally occluded. In the embodiment shown in FIG. 19B, a second pair of valve end stops 1227 are provided to the second flow vectoring air outlet 1203 when the second flow vectoring air outlet 1204 is nearly, but not completely, occluded. It is arranged to abut a portion of the adjacent inner casing 1214 . As a result, the amount of airflow emitted from the first flow vectoring air outlet 1203 will be significantly higher than the airflow emitted from the second flow vectoring air outlet 1204, so that the resulting impact from their collision is directed generally downward from the face 1208 of the nozzle 1200 (i.e., in a direction generally parallel to the direction of airflow emitted from the first flow vectoring air outlet 1203), as indicated by arrow BB. will be taken.

Further, in the illustrated embodiment, the first and second flange portions 1228, 1229 of the valve member 1207 are positioned when the valve member 1207 is in the first end position (i.e., the first flow vectoring air outlet 1203 is closed). and the second flow vectoring air outlet 1204), the side air outlets 1217, 1218 are arranged to be maximally occluded/closed. As a result, none of the airflow generated by the motor driven impeller 1110 is emitted from the side air outlets 1217,1218.

It will be readily appreciated that the examples of Figures 19A and 19B are merely representative and represent extreme cases in practice. By sliding the valve member 1207 into positions between the first and second end positions, a wide variety of resulting airflows can be achieved. For example, in the illustrated embodiment, the variable range of the synthetic airflow generated by nozzle 1200 is approximately 44 degrees. Specifically, the nozzle 1200 of the illustrated embodiment has a nozzle Between the first extreme of 37.5 degrees with respect to base 1209 of nozzle 1200 and the second extreme of -6.5 degrees with respect to base 1209 of nozzle 1200, the direction of the combined airflow (γ) is can be changed. The direction of the resultant airflow can then be further varied by controlling the vibration motor 1129 to adjust the angular position of the nozzle body 1201 relative to the body 1100 of the fan assembly 1000 .

The fact that each individual item described above can be used alone or in combination with other items shown in the drawings or described in the specification, and that items shown in the same section as each other or in the same drawings as each other must be used in combination with each other. It should be understood that there is no Further, the expression "means" may be replaced with actuators or systems or devices as appropriate. Additionally, references to "comprising" or "consisting of" are not intended to be limiting in any way, and the reader should interpret the specification and claims accordingly.

Additionally, while the invention has been described in terms of preferred embodiments, as noted above, it is to be understood that these embodiments are illustrative only. Modifications and alternatives may be made by those skilled in the art in light of this disclosure and are intended to fall within the scope of the appended claims. For example, those skilled in the art will appreciate that the above-described invention is equally applicable not only to free-standing fan assemblies, but also to other types of climate control fan assemblies. By way of example, such fan assemblies may be free standing fan assemblies, ceiling mounted or wall mounted fan assemblies, and vehicle mounted fan assemblies. Furthermore, the above-described invention is equally applicable to other types of airflow generating devices or blowers, such as hair dryers or other hair care appliances.

As another example, while the valve mechanism described above includes a single linearly movable valve member, the valve mechanism may vary the size of the first flow vectoring air outlet to that of the second flow vectoring air outlet. It is equally possible to include multiple valve members that cooperate to adjust for size. To that end, multiple valve members can be linked so that they move simultaneously. Further, while the embodiments described above use a manual mechanism to drive movement of the valve member, the nozzles described herein instead provide movement of the valve member in response to commands received from a control circuit. may include a valve motor for driving the

Additionally, the nozzles and outlets can have different shapes than those described above. For example, rather than having the general shape of an arc, the slots providing the first and second flow vectoring air outlets may each be elongated or elliptical arcs. Similarly, rather than having the general shape of a sphere, the nozzle can have the general shape of a cube, ellipsoid or spheroid. In that case, the face of the nozzle can be square, rectangular or oval rather than circular.

As yet another example, in the above-described embodiment, the valve member is provided with both an asymmetrical end stop and an asymmetrical profile to bias the direction of the combined airflow forward of the nozzle, but these features are mutually exclusive. Can be used independently. In particular, some degree of bias can be achieved using either asymmetrical end stops or an asymmetrical profile on the valve member.

1202 air inlet 1203 first flow vectoring air outlet 1207 valve member 1208 circular face/face 1210 outer casing 1211 circular opening on circular face 1212 circular opening on circular base 1213 lip 1214 inner casing 1214c first stepped side portion 1214d second stepped side portion 1215 first side duct 1216 second side duct 1217 outlet opening or side air outlet 1218 outlet opening or side air outlet 1219 pair of vanes/air directing vanes 1220 spindle 1221 Air inlet guide member 1234a Retaining element/movable catch 1234b Manually actuatable member/depressible button 1234c Biasing member 1235a Retaining element/movable catch 1235b Manually actuable member/depressible button 1235c Biasing member 1239a Upper filter sealing element 1239b Annular plate

According to a further aspect, a fan assembly comprising a fan body, a motor driven impeller housed within the fan body and arranged to generate an airflow, and arranged to receive the airflow from the fan body. a nozzle for releasably retaining the nozzle on the fan body; A fan assembly is provided that includes a retention mechanism and a rotation mechanism for rotating the nozzle body relative to the fan body. The nozzle rotation mechanism includes a rotary motor arranged to drive a driving member and a driven member arranged to rotate about an axis of rotation driven by the driving member, the nozzle body being driven by the driven member. The fan body includes a rotating motor and a drive member . The driving member includes a pinion and the driven member includes an at least partially circular or arcuate rack. The pinion comprises a linear gear with a chamfered upper portion and the rack comprises a linear rack with a chamfered lower portion.

The lower section provides a compartment 1105 in which the various electronic components of the fan assembly 1000 are housed, and a cradle overlies the electronic components and separates them from the rest of the fan assembly. form a cover; For example, these electronic components typically include control circuitry 1106, power connections, and one or more sensors such as infrared sensors, dust sensors, and the like. Additionally, the lower section of the body can also house one or more wireless communication modules, such as Wi- Fi® , Bluetooth®, etc., as well as any associated electronics. The lower section may further comprise an electronic display 1107 visible through an opening or at least partially transparent window provided in the lower section. In the illustrated embodiment, the electronic display 1107 is mounted in the lower section and is exposed to both corresponding openings in the sidewalls of the cradle 1104 and transparent windows in the sidewalls of the outer casing 1101. Provided by an aligned LCD display.

Claims (20)

A fan assembly,
the fan body,
a motor driven impeller housed within the fan body and positioned to generate an airflow;
a nozzle including a nozzle body having an air inlet positioned to receive the airflow from the fan body and one or more air outlets positioned to emit the airflow from the fan assembly; ,
a nozzle holding mechanism for detachably holding the nozzle on the fan body;
a rotary mechanism for rotating the nozzle body relative to the fan body, the rotary motor arranged to drive a drive member; and a rotary motor driven by the drive member to rotate about an axis of rotation. a rotating mechanism comprising a driven member disposed in a
with
A fan assembly, wherein the nozzle body includes the driven member, and the fan body includes the rotary motor and the drive member. 2. The fan set of claim 1, wherein the nozzle retention mechanism has a first configuration in which the nozzle is retained on the fan body and a second configuration in which the nozzle is released for removal from the fan body. three-dimensional. 2. The fan assembly of claim 1, wherein said nozzle retention mechanism includes a retention element movable relative to said nozzle and said body between said first configuration and said second configuration. 4. A fan assembly as claimed in claim 3, wherein the retaining element includes a catch. 5. The fan body of claim 4, wherein the fan body comprises a circular or arcuate lip arranged to be engaged by a catch of the nozzle retention mechanism to thereby retain the nozzle to the body in the first configuration. A fan assembly as described. A fan assembly as claimed in any preceding claim, wherein the driven member comprises a pinion and the driving member comprises an at least partially circular or arcuate rack. 7. A fan assembly as claimed in claim 6, wherein the pinion comprises a linear gear with a chamfered upper portion. 8. A fan assembly as claimed in any one of claims 6 or 7, wherein the rack comprises a straight rack having a chamfered lower portion. 9. The nozzle body of any one of claims 1-8, wherein the nozzle body comprises at least one stop positioned to prevent rotation of the nozzle body beyond the end of the nozzle body's range of rotation. A fan assembly as described in paragraph 1. 10. The stop or stops further arranged to prevent the nozzle from being mounted on the fan body when oriented out of the range of rotation of the nozzle body relative to the fan body. A fan assembly as described. The nozzle further comprises a base member positioned to contact the fan body when the nozzle is mounted on the fan body, the nozzle body being rotatable relative to the base member. Item 11. The fan assembly according to any one of items 1 to 10. 12. A fan assembly as claimed in claim 11, wherein the nozzle body comprises a plurality of runners arranged to retain the base member while allowing the base member to rotate relative to the nozzle body. . 13. A fan assembly as claimed in claim 12, wherein the base member comprises rails disposed within and sliding within each of the plurality of runners. A fan assembly as claimed in any preceding claim, wherein the fan assembly further comprises a filter assembly mounted over at least a portion of the fan body. 15. A fan assembly as claimed in Claim 14 when dependent on Claim 11, wherein the base member of the nozzle further comprises an upper filter seal element positioned to contact an upper surface of the filter assembly. 16. A fan as claimed in claim 15, wherein the upper filter seal element is arranged to contact a surface of the fan body thereby forming a seal between a lower surface of the base member and the fan body. assembly. A fan set as claimed in any one of claims 14 to 16, wherein the fan body comprises an upper section and a lower section, the lower section providing a filter seat on which the filter assembly is supported. three-dimensional. 18. A fan assembly as claimed in claim 17, wherein the upper section of the fan body comprises a filter compartment in which the filter assembly is located. 19. A fan assembly as claimed in claim 18, wherein the filter section has an open top end that allows the filter assembly to be inserted into and removed from the filter section. A nozzle for a fan assembly, comprising:
a nozzle body having an air inlet positioned to receive airflow from the body of the fan assembly and one or more air outlets positioned to emit the airflow from the nozzle;
a nozzle holding mechanism for detachably holding the nozzle on the body of the fan assembly;
a driven member arranged to be driven by the drive member to rotate the nozzle body about an axis of rotation;
a nozzle.

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